1 / 47

Chapter 8 - Operator Overloading

Chapter 8 - Operator Overloading. Outline 8.1 Introduction 8.2 Fundamentals of Operator Overloading 8.3 Restrictions on Operator Overloading 8.4 Operator Functions as Class Members vs. as friend Functions 8.5 Overloading Stream-Insertion and Stream-Extraction Operators

vanhouten
Download Presentation

Chapter 8 - Operator Overloading

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Chapter 8 - Operator Overloading Outline 8.1 Introduction 8.2 Fundamentals of Operator Overloading 8.3 Restrictions on Operator Overloading 8.4 Operator Functions as Class Members vs. as friend Functions 8.5 Overloading Stream-Insertion and Stream-Extraction Operators 8.6 Overloading Unary Operators 8.7 Overloading Binary Operators 8.8 Case Study: An Array Class 8.9 Converting between Types 8.10 Case Study: A String Class 8.11 Overloading ++ and -- 8.12 Case Study: A Date Class

  2. 8.1 Introduction • Operator overloading • Enabling C++’s operators to work with class objects • Using traditional operators with user-defined objects • Requires great care; when overloading is misused, program difficult to understand • Examples of already overloaded operators • Operator << is both the stream-insertion operator and the bitwise left-shift operator • + and -, perform arithmetic on multiple types • Compiler generates the appropriate code based on the manner in which the operator is used

  3. 8.2 Fundamentals of Operator Overloading • Overloading an operator • Write function definition as normal • Function name is keyword operator followed by the symbol for the operator being overloaded • operator+ used to overload the addition operator (+) • Using operators • To use an operator on a class object it must be overloaded unless the assignment operator(=)or the address operator(&) • Assignment operator by default performs memberwise assignment • Address operator (&) by default returns the address of an object

  4. 8.3 Restrictions on Operator Overloading • C++ operators that can be overloaded • C++ Operators that cannot be overloaded

  5. 8.3 Restrictions on Operator Overloading • Overloading restrictions • Precedence of an operator cannot be changed • Associativity of an operator cannot be changed • Arity (number of operands) cannot be changed • Unary operators remain unary, and binary operators remain binary • Operators &, *, + and - each have unary and binary versions • Unary and binary versions can be overloaded separately • No new operators can be created • Use only existing operators • No overloading operators for built-in types • Cannot change how two integers are added • Produces a syntax error

  6. 8.4 Operator Functions as Class Members vs. as friend Functions • Member vs non-member • Operator functions can be member or non-member functions • When overloading (), [], -> or any of the assignment operators, must use a member function • Operator functions as member functions • Leftmost operand must be an object (or reference to an object) of the class • If left operand of a different type, operator function must be a non-member function • Operator functions as non-member functions • Must be friends if needs to access private or protected members • Enable the operator to be commutative

  7. 8.5 Overloading Stream-Insertion and Stream-Extraction Operators • Overloaded << and >> operators • Overloaded to perform input/output for user-defined types • Left operand of types ostream& and istream& • Must be a non-member function because left operand is not an object of the class • Must be a friend function to access private data members

  8. 1 // Fig. 8.3: fig08_03.cpp 2 // Overloading the stream-insertion and 3 // stream-extraction operators. 4 #include <iostream> Notice function prototypes for overloaded operators >> and << They must be friend functions. 5 6 using std::cout; 7 using std::cin; 8 using std::endl; 9 using std::ostream; 10 using std::istream; 11 12 #include <iomanip> 13 14 using std::setw; 15 16 class PhoneNumber { 17 friend ostream &operator<<( ostream&, const PhoneNumber & ); 18 friend istream &operator>>( istream&, PhoneNumber & ); 19 20 private: 21 char areaCode[ 4 ]; // 3-digit area code and null 22 char exchange[ 4 ]; // 3-digit exchange and null 23 char line[ 5 ]; // 4-digit line and null 24 }; 25 26 // Overloaded stream-insertion operator (cannot be 27 // a member function if we would like to invoke it with 28 // cout << somePhoneNumber;). 29 ostream &operator<<( ostream &output, const PhoneNumber &num ) 30 { 1. Class definition 1.1 Function definitions

  9. 31 output << "(" << num.areaCode << ") " 32 << num.exchange << "-" << num.line; 33 return output; // enables cout << a << b << c; 34 } The function call cin >> phone; interpreted as operator>>(cin, phone); input is an alias for cin, and num is an alias for phone. 35 36 istream &operator>>( istream &input, PhoneNumber &num ) 37 { 38 input.ignore(); // skip ( 39 input >> setw( 4 ) >> num.areaCode; // input area code 40 input.ignore( 2 ); // skip ) and space 41 input >> setw( 4 ) >> num.exchange; // input exchange 42 input.ignore(); // skip dash (-) 43 input >> setw( 5 ) >> num.line; // input line 44 return input; // enables cin >> a >> b >> c; 45 } 46 47 int main() 48 { 49 PhoneNumber phone; // create object phone 50 51 cout << "Enter phone number in the form (123) 456-7890:\n"; 52 53 // cin >> phone invokes operator>> function by 54 // issuing the call operator>>( cin, phone ). 55 cin >> phone; 56 57 // cout << phone invokes operator<< function by 58 // issuing the call operator<<( cout, phone ). 59 cout << "The phone number entered was: " << phone << endl; 60 return 0; 61 } 1.1 Function definition 1.2 Initialize variables 2. Get input 2.1 Assign to object 2.2 Output data

  10. Enter phone number in the form (123) 456-7890: (800) 555-1212 The phone number entered was: (800) 555-1212 Program Output

  11. 8.6 Overloading Unary Operators • Overloading unary operators • Can be overloaded with no arguments or one argument • Should usually be implemented as member functions • Avoid friend functions and classes because they violate the encapsulation of a class • Example declaration as a member function: class String {public: bool operator!() const; ...};

  12. 8.6 Overloading Unary Operators • Example declaration as a non-member function class String { friend bool operator!( const String & ) ...}

  13. 8.7 Overloading Binary Operators • Overloaded Binary operators • Non-static member function, one argument • Example: class String { public: const String &operator+=( const String & ); ... }; • y += z is equivalent to y.operator+=( z )

  14. 8.7 Overloading Binary Operators • Non-member function, two arguments • Example: class String { friend const String &operator+=( String &, const String & ); ... }; • y += z is equivalent to operator+=( y, z )

  15. 8.8 Case Study: An Array class • Implement an Array class with • Range checking • Array assignment • Arrays that know their size • Outputting/inputting entire arrays with << and >> • Array comparisons with == and !=

  16. 1 // Fig. 8.4: array1.h 2 // Simple class Array (for integers) 3 #ifndef ARRAY1_H 4 #define ARRAY1_H 5 6 #include <iostream> Notice all the overloaded operators used to implement the class. 7 8 using std::ostream; 9 using std::istream; 10 11 class Array { 12 friend ostream &operator<<( ostream &, const Array & ); 13 friend istream &operator>>( istream &, Array & ); 14 public: 15 Array( int = 10 ); // default constructor 16 Array( const Array & ); // copy constructor 17 ~Array(); // destructor 18 int getSize() const; // return size 19 const Array &operator=( const Array & ); // assign arrays 20 bool operator==( const Array & ) const; // compare equal 21 22 // Determine if two arrays are not equal and 23 // return true, otherwise return false (uses operator==). 24 bool operator!=( const Array &right ) const 25 { return ! ( *this == right ); } 26 27 int &operator[]( int ); // subscript operator 28 constint &operator[]( int ) const; // subscript operator 29 static int getArrayCount(); // Return count of 30 // arrays instantiated. 31 private: 32 int size; // size of the array 33 int *ptr; // pointer to first element of array 34 static int arrayCount; // # of Arrays instantiated 1. Class definition 1.1 Function prototypes

  17. 35 }; 38 // Fig 8.4: array1.cpp 36 39 // Member function definitions for class Array 37 #endif 40 #include <iostream> 41 42 using std::cout; 43 using std::cin; 44 using std::endl; 45 46 #include <iomanip> 47 48 using std::setw; 49 50 #include <cstdlib> 51 #include <cassert> 52 #include "array1.h" 53 54 // Initialize static data member at file scope 55 int Array::arrayCount = 0; // no objects yet 56 57 // Default constructor for class Array (default size 10) 58 Array::Array( int arraySize ) 59 { 60 size = ( arraySize > 0 ? arraySize : 10 ); 61 ptr = newint[ size ]; // create space for array 62 assert( ptr != 0 ); // terminate if memory not allocated 63 ++arrayCount; // count one more object 64 65 for ( int i = 0; i < size; i++ ) 66 ptr[ i ] = 0; // initialize array 1. Load header 1.1 Function definitions 1.2 Array constructor

  18. 67 } 68 69 // Copy constructor for class Array 70 // must receive a reference to prevent infinite recursion 71 Array::Array( const Array &init ) : size( init.size ) 72 { 73 ptr = newint[ size ]; // create space for array 74 assert( ptr != 0 ); // terminate if memory not allocated 75 ++arrayCount; // count one more object 76 77 for ( int i = 0; i < size; i++ ) 78 ptr[ i ] = init.ptr[ i ]; // copy init into object 79 } 80 81 // Destructor for class Array 82 Array::~Array() 83 { 84 delete [] ptr; // reclaim space for array 85 --arrayCount; // one fewer object 86 } 87 88 // Get the size of the array 89 int Array::getSize() const { return size; } 90 91 // Overloaded assignment operator 92 // const return avoids: ( a1 = a2 ) = a3 93 const Array &Array::operator=( const Array &right ) 94 { 95 if ( &right != this ) { // check for self-assignment 96 97 // for arrays of different sizes, deallocate original 98 // left side array, then allocate new left side array. 99 if ( size != right.size ) { 100 delete [] ptr; // reclaim space 1.3 Array destructor 1.4 operator= (assignment)

  19. 101 size = right.size; // resize this object 102 ptr = new int[ size ]; // create space for array copy 103 assert( ptr != 0 ); // terminate if not allocated 104 } 105 106 for ( int i = 0; i < size; i++ ) 107 ptr[ i ] = right.ptr[ i ]; // copy array into object 108 } 109 110 return *this; // enables x = y = z; 111 } 112 113 // Determine if two arrays are equal and 114 // return true, otherwise return false. 115 bool Array::operator==( const Array &right ) const 116 { 117 if ( size != right.size ) 118 return false; // arrays of different sizes 119 120 for ( int i = 0; i < size; i++ ) 121 if ( ptr[ i ] != right.ptr[ i ] ) 122 returnfalse; // arrays are not equal 123 124 return true; // arrays are equal 125 } 126 127 // Overloaded subscript operator for non-const Arrays 128 // reference return creates an lvalue 129 int &Array::operator[]( int subscript ) 130 { 131 // check for subscript out of range error 132 assert( 0 <= subscript && subscript < size ); 1.5 operator== (equality) 1.6 operator[] (subscript for non-constarrays)

  20. 133 134 return ptr[ subscript ]; // reference return 135 } 136 137 // Overloaded subscript operator for const Arrays 138 // const reference return creates an rvalue 139 const int &Array::operator[]( int subscript ) const 140 { 141 // check for subscript out of range error 142 assert( 0 <= subscript && subscript < size ); 143 144 return ptr[ subscript ]; // const reference return 145 } 146 147 // Return the number of Array objects instantiated 148 // static functions cannot be const 149 int Array::getArrayCount() { return arrayCount; } 150 151 // Overloaded input operator for class Array; 152 // inputs values for entire array. 153 istream &operator>>( istream &input, Array &a ) 154 { 155 for ( int i = 0; i < a.size; i++ ) 156 input >> a.ptr[ i ]; 157 158 return input; // enables cin >> x >> y; 159 } 160 161 // Overloaded output operator for class Array 162 ostream &operator<<( ostream &output, const Array &a ) 163 { 1.6 operator[] (subscript for constarrays) 1.7 getArrayCount 1.8 operator>> (input array) 1.9 operator<< (output array)

  21. 178 // Fig. 8.4: fig08_04.cpp 164 int i; 165 179 // Driver for simple class Array 166 for ( i = 0; i < a.size; i++ ) { 180 #include <iostream> 167 output << setw( 12 ) << a.ptr[ i ]; 181 182 using std::cout; 168 183 using std::cin; 169 if ( ( i + 1 ) % 4 == 0 ) // 4 numbers per row of output 170 output << endl; 184 using std::endl; 171 } 185 186 #include "array1.h" 172 173 if ( i % 4 != 0 ) 187 188 int main() 174 output << endl; 175 189 { 190 // no objects yet 176 return output; // enables cout << x << y; 177 } 191 cout << "# of arrays instantiated = " 192 << Array::getArrayCount() << '\n'; 193 1. Load header # of arrays instantiated = 0

  22. 194 // create two arrays and print Array count 195 Array integers1( 7 ), integers2; 196 cout << "# of arrays instantiated = " 197 << Array::getArrayCount() << "\n\n"; 198 199 // print integers1 size and contents 200 cout << "Size of array integers1 is " 201 << integers1.getSize() 202 << "\nArray after initialization:\n" 203 << integers1 << '\n'; 204 205 // print integers2 size and contents 206 cout << "Size of array integers2 is " 207 << integers2.getSize() 208 << "\nArray after initialization:\n" 209 << integers2 << '\n'; 210 211 // input and print integers1 and integers2 212 cout << "Input 17 integers:\n"; 213 cin >> integers1 >> integers2; 214 cout << "After input, the arrays contain:\n" 215 << "integers1:\n" << integers1 216 << "integers2:\n" << integers2 << '\n'; 217 218 // use overloaded inequality (!=) operator 219 cout << "Evaluating: integers1 != integers2\n"; 220 if ( integers1 != integers2 ) 221 cout << "They are not equal\n"; 222 223 // create array integers3 using integers1 as an 224 // initializer; print size and contents 225 Array integers3( integers1 ); 226 # of arrays instantiated = 2 1.1 Initialize objects 2. Function calls Size of array integers1 is 7 Array after initialization: 0 0 0 0 0 0 0 Size of array integers2 is 10 Array after initialization: 0 0 0 0 0 0 0 0 0 0 Input 17 integers: 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 After input, the arrays contain: integers1: 1 2 3 4 5 6 7 integers2: 8 9 10 11 12 13 14 15 16 17 Evaluating: integers1 != integers2 They are not equal

  23. 227 cout << "\nSize of array integers3 is " 228 << integers3.getSize() 229 << "\nArray after initialization:\n" 230 << integers3 << '\n'; 231 232 // use overloaded assignment (=) operator 233 cout << "Assigning integers2 to integers1:\n"; 234 integers1 = integers2; 235 cout << "integers1:\n" << integers1 236 << "integers2:\n" << integers2 << '\n'; 237 238 // use overloaded equality (==) operator 239 cout << "Evaluating: integers1 == integers2\n"; 240 if ( integers1 == integers2 ) 241 cout << "They are equal\n\n"; 242 243 // use overloaded subscript operator to create rvalue 244 cout << "integers1[5] is " << integers1[ 5 ] << '\n'; 245 246 // use overloaded subscript operator to create lvalue 247 cout << "Assigning 1000 to integers1[5]\n"; 248 integers1[ 5 ] = 1000; 249 cout << "integers1:\n" << integers1 << '\n'; 250 251 // attempt to use out of range subscript 252 cout << "Attempt to assign 1000 to integers1[15]" << endl; 253 integers1[ 15 ] = 1000; // ERROR: out of range 254 255 return 0; 256 } 2. Function calls Size of array integers3 is 7 Array after initialization: 1 2 3 4 5 6 7 Assigning integers2 to integers1: integers1: 8 9 10 11 12 13 14 15 16 17 integers2: 8 9 10 11 12 13 14 15 16 17 Evaluating: integers1 == integers2 They are equal integers1[5] is 13 Attempt to assign 1000 to integers1[15] Assertion failed: 0 <= subscript && subscript < size, file Array1.cpp, line 95 abnormal program termination Assigning 1000 to integers1[5] integers1: 8 9 10 11 12 1000 14 15 16 17

  24. # of arrays instantiated = 0 # of arrays instantiated = 2 Size of array integers1 is 7 Array after initialization: 0 0 0 0 0 0 0 Size of array integers2 is 10 Array after initialization: 0 0 0 0 0 0 0 0 0 0 Input 17 integers: 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 After input, the arrays contain: integers1: 1 2 3 4 5 6 7 integers2: 8 9 10 11 12 13 14 15 16 17 Evaluating: integers1 != integers2 They are not equal Size of array integers3 is 7 Array after initialization: 1 2 3 4 5 6 7 Program Output

  25. Assigning integers2 to integers1: integers1: 8 9 10 11 12 13 14 15 16 17 integers2: 8 9 10 11 12 13 14 15 16 17 Evaluating: integers1 == integers2 They are equal integers1[5] is 13 Assigning 1000 to integers1[5] integers1: 8 9 10 11 12 1000 14 15 16 17 Attempt to assign 1000 to integers1[15] Assertion failed: 0 <= subscript && subscript < size, file Array1.cpp, line 95 abnormal program termination Program Output

  26. 8.9 Converting between Types • Cast operator • Forces conversions among built-in types • Specifies conversions between user defined and built-in types • Conversion operator must be a non-static member function • Cannot be a friend function • Do not specify return type • Return type is the type to which the object is being converted • For user-defined class A A::operator char *() const; • Declares an overloaded cast operator function for creating a char* out of an A object

  27. 8.9 Converting between Types A::operator int() const; • Declares an overloaded cast operator function for converting an object of A into an integer A::operator otherClass() const; • Declares an overloaded cast operator function for converting an object of A into an object of otherClass • Compiler and casting • Casting can prevent the need for overloading • If an object s of user-defined class String appears in a program where an ordinary char* is expected, such as cout << s; The compiler calls the overloaded cast operator function operatorchar* to convert the object into a char* and uses the resulting char* in the expression

  28. 8.10 Case Study: A String Class • Build a class to handle strings • Class string in standard library (more Chapter 19) • Conversion constructor • Single-argument constructors that turn objects of other types into class objects

  29. 1 // Fig. 8.5: string1.h 2 // Definition of a String class 3 #ifndef STRING1_H 4 #define STRING1_H 5 6 #include <iostream> 7 8 using std::ostream; 9 using std::istream; 10 11 class String { 12 friend ostream &operator<<( ostream &, const String & ); 13 friend istream &operator>>( istream &, String & ); 14 15 public: 16 String( const char * = "" ); // conversion/default ctor 17 String( const String & ); // copy constructor 18 ~String(); // destructor 19 const String &operator=( const String & ); // assignment 20 const String &operator+=( const String & ); // concatenation 21 bool operator!() const; // is String empty? 22 bool operator==( const String & ) const; // test s1 == s2 23 bool operator<( const String & ) const; // test s1 < s2 24 25 // test s1 != s2 26 bool operator!=( const String & right ) const 27 { return !( *this == right ); } 28 29 // test s1 > s2 30 bool operator>( const String &right ) const 31 { return right < *this; } 32 33 // test s1 <= s2 1. Class definition 1.1 Member functions, some definitions

  30. 34 bool operator<=( const String &right ) const 54 // Fig. 8.5: string1.cpp 35 { return !( right < *this ); } 55 // Member function definitions for class String 36 56 #include <iostream> 57 37 // test s1 >= s2 38 bool operator>=( const String &right ) const 58 using std::cout; 59 using std::endl; 39 { return !( *this < right ); } 60 40 61 #include <iomanip> 41 char &operator[]( int ); // subscript operator 62 42 const char &operator[]( int ) const; // subscript operator 63 using std::setw; 43 String operator()( int, int ); // return a substring 64 44 int getLength() const; // return string length 45 46 private: 47 int length; // string length 48 char *sPtr; // pointer to start of string 49 50 void setString( const char * ); // utility function 51 }; 52 53 #endif 1.2 Member variables

  31. 65 #include <cstring> 66 #include <cassert> 67 #include "string1.h" 68 Conversion constructor: char * to String. 69 // Conversion constructor: Convert char * to String 70 String::String( const char *s ) : length( strlen( s ) ) 71 { 72 cout << "Conversion constructor: " << s << '\n'; Constructors and destructors will print when called. 73 setString( s ); // call utility function 74 } 75 76 // Copy constructor 77 String::String( const String &copy ) : length( copy.length ) 78 { 79 cout << "Copy constructor: " << copy.sPtr << '\n'; 80 setString( copy.sPtr ); // call utility function 81 } 82 83 // Destructor 84 String::~String() 85 { 86 cout << "Destructor: " << sPtr << '\n'; 87 delete [] sPtr; // reclaim string 88 } 89 90 // Overloaded = operator; avoids self assignment 91 const String &String::operator=( const String &right ) 92 { 93 cout << "operator= called\n"; 94 95 if ( &right != this ) { // avoid self assignment 1. Load header 1.1 Function definitions 1.2 Conversion constructor 1.3 Copy constructor 1.4 Destructor 1.5 operator= (assignment)

  32. 96 delete [] sPtr; // prevents memory leak 97 length = right.length; // new String length 98 setString( right.sPtr ); // call utility function 99 } 100 else 101 cout << "Attempted assignment of a String to itself\n"; 102 103 return *this; // enables cascaded assignments 104 } 105 106 // Concatenate right operand to this object and 107 // store in this object. 108 const String &String::operator+=( const String &right ) 109 { 110 char *tempPtr = sPtr; // hold to be able to delete 111 length += right.length; // new String length 112 sPtr = new char[ length + 1 ]; // create space 113 assert( sPtr != 0 ); // terminate if memory not allocated 114 strcpy( sPtr, tempPtr ); // left part of new String 115 strcat( sPtr, right.sPtr ); // right part of new String 116 delete [] tempPtr; // reclaim old space 117 return *this; // enables cascaded calls 118 } 119 120 // Is this String empty? 121 bool String::operator!() const { return length == 0; } 122 123 // Is this String equal to right String? 124 bool String::operator==( const String &right ) const 125 { return strcmp( sPtr, right.sPtr ) == 0; } 126 127 // Is this String less than right String? 1.6 operator+= (concatenation) 1.7 operator! (string empty?) 1.8 operator== (equality)

  33. 128 bool String::operator<( const String &right ) const 129 { return strcmp( sPtr, right.sPtr ) < 0; } 130 131 // Return a reference to a character in a String as an lvalue. 132 char &String::operator[]( int subscript ) 133 { 134 // First test for subscript out of range Notice the overloaded function call operator. 135 assert( subscript >= 0 && subscript < length ); 136 137 return sPtr[ subscript ]; // creates lvalue 138 } 139 140 // Return a reference to a character in a String as an rvalue. 141 const char &String::operator[]( int subscript ) const 142 { 143 // First test for subscript out of range 144 assert( subscript >= 0 && subscript < length ); 145 146 return sPtr[ subscript ]; // creates rvalue 147 } 148 149 // Return a substring beginning at index and 150 // of length subLength 151 String String::operator()( int index, int subLength ) 152 { 153 // ensure index is in range and substring length >= 0 154 assert( index >= 0 && index < length && subLength >= 0 ); 155 156 // determine length of substring 157 int len; 158 1.9 operator< (less than) 1.10 operator[] (subscript) 1.11 operator[] (constsubscript) 1.12 operator() (return substring)

  34. 159 if ( ( subLength == 0 ) || ( index + subLength > length ) ) 160 len = length - index; 161 else 162 len = subLength; 163 164 // allocate temporary array for substring and 165 // terminating null character 166 char *tempPtr = new char[ len + 1 ]; 167 assert( tempPtr != 0 ); // ensure space allocated 168 169 // copy substring into char array and terminate string 170 strncpy( tempPtr, &sPtr[ index ], len ); 171 tempPtr[ len ] = '\0'; 172 173 // Create temporary String object containing the substring 174 String tempString( tempPtr ); 175 delete [] tempPtr; // delete the temporary array 176 177 return tempString; // return copy of the temporary String 178 } 179 180 // Return string length 181 int String::getLength() const { return length; } 182 183 // Utility function to be called by constructors and 184 // assignment operator. 185 void String::setString( const char *string2 ) 186 { 187 sPtr = new char[ length + 1 ]; // allocate storage 188 assert( sPtr != 0 ); // terminate if memory not allocated 189 strcpy( sPtr, string2 ); // copy literal to object 190 } 1.13 getLength 1.14 setString

  35. 208 // Fig. 8.5: fig08_05.cpp 191 192 // Overloaded output operator 209 // Driver for class String 193 ostream &operator<<( ostream &output, const String &s ) 210 #include <iostream> 194 { 211 195 output << s.sPtr; 212 using std::cout; 196 return output; // enables cascading 213 using std::endl; 197 } 214 215 #include "string1.h" 198 199 // Overloaded input operator 216 Conversion constructor: happy Conversion constructor: birthday Conversion constructor: 217 int main() 200 istream &operator>>( istream &input, String &s ) 201 { 218 { 219 String s1( "happy" ), s2( " birthday" ), s3; 202 char temp[ 100 ]; // buffer to store input 220 203 204 input >> setw( 100 ) >> temp; 205 s = temp; // use String class assignment operator 206 return input; // enables cascading 207 } 1.15 operator<< (output String) 1.16 operator>> (input String) ----------------------- 1. Load header 1.1 Initialize objects

  36. 221 // test overloaded equality and relational operators 222 cout << "s1 is \"" << s1 << "\"; s2 is \"" << s2 223 << "\"; s3 is \"" << s3 << '\"' 224 << "\nThe results of comparing s2 and s1:" 225 << "\ns2 == s1 yields " 226 << ( s2 == s1 ? "true" : "false" ) 227 << "\ns2 != s1 yields " 228 << ( s2 != s1 ? "true" : "false" ) 229 << "\ns2 > s1 yields " 230 << ( s2 > s1 ? "true" : "false" ) 231 << "\ns2 < s1 yields " 232 << ( s2 < s1 ? "true" : "false" ) 233 << "\ns2 >= s1 yields " 234 << ( s2 >= s1 ? "true" : "false" ) 235 << "\ns2 <= s1 yields " 236 << ( s2 <= s1 ? "true" : "false" ); 237 238 // test overloaded String empty (!) operator 239 cout << "\n\nTesting !s3:\n"; 240 if ( !s3 ) { 241 cout << "s3 is empty; assigning s1 to s3;\n"; 242 s3 = s1; // test overloaded assignment 243 cout << "s3 is \"" << s3 << "\""; 244 } 245 246 // test overloaded String concatenation operator 247 cout << "\n\ns1 += s2 yields s1 = "; 248 s1 += s2; // test overloaded concatenation 249 cout << s1; 250 251 // test conversion constructor 252 cout << "\n\ns1 += \" to you\" yields\n"; 253 s1 += " to you"; // test conversion constructor 2. Function calls s1 is "happy"; s2 is " birthday"; s3 is "" The results of comparing s2 and s1: s2 == s1 yields false s2 != s1 yields true s2 > s1 yields false s2 < s1 yields true s2 >= s1 yields false s2 <= s1 yields true Testing !s3: s3 is empty; assigning s1 to s3; operator= called s3 is "happy" s1 += s2 yields s1 = happy birthday s1 += " to you" yields Conversion constructor: to you Destructor: to you

  37. 254 cout << "s1 = " << s1 << "\n\n"; 255 256 // test overloaded function call operator () for substring 257 cout << "The substring of s1 starting at\n" 258 << "location 0 for 14 characters, s1(0, 14), is:\n" 259 << s1( 0, 14 ) << "\n\n"; 260 261 // test substring "to-end-of-String" option 262 cout << "The substring of s1 starting at\n" 263 << "location 15, s1(15, 0), is: " 264 << s1( 15, 0 ) << "\n\n"; // 0 is "to end of string" 265 266 // test copy constructor 267 String *s4Ptr = new String( s1 ); 268 cout << "*s4Ptr = " << *s4Ptr << "\n\n"; 269 270 // test assignment (=) operator with self-assignment 271 cout << "assigning *s4Ptr to *s4Ptr\n"; 272 *s4Ptr = *s4Ptr; // test overloaded assignment 273 cout << "*s4Ptr = " << *s4Ptr << '\n'; 274 275 // test destructor 276 delete s4Ptr; 277 278 // test using subscript operator to create lvalue 279 s1[ 0 ] = 'H'; 280 s1[ 6 ] = 'B'; 281 cout << "\ns1 after s1[0] = 'H' and s1[6] = 'B' is: " 282 << s1 << "\n\n"; 283 s1 = happy birthday to you 2. Function calls Conversion constructor: happy birthday Copy constructor: happy birthday Destructor: happy birthday The substring of s1 starting at location 0 for 14 characters, s1(0, 14), is: happy birthday Destructor: happy birthday Conversion constructor: to you Copy constructor: to you Destructor: to you The substring of s1 starting at location 15, s1(15, 0), is: to you Destructor: to you Copy constructor: happy birthday to you *s4Ptr = happy birthday to you assigning *s4Ptr to *s4Ptr operator= called Attempted assignment of a String to itself *s4Ptr = happy birthday to you Destructor: happy birthday to you s1 after s1[0] = 'H' and s1[6] = 'B' is: Happy Birthday to you

  38. 284 // test subscript out of range 285 cout << "Attempt to assign 'd' to s1[30] yields:" << endl; 286 s1[ 30 ] = 'd'; // ERROR: subscript out of range Attempt to assign 'd' to s1[30] yields: Assertion failed: subscript >= 0 && subscript < length, file string1.cpp, line 82 Abnormal program termination 287 Conversion constructor: happy Conversion constructor: birthday Conversion constructor: s1 is "happy"; s2 is " birthday"; s3 is "" The results of comparing s2 and s1: s2 == s1 yields false s2 != s1 yields true s2 > s1 yields false s2 < s1 yields true s2 >= s1 yields false s2 <= s1 yields true Testing !s3: s3 is empty; assigning s1 to s3; operator= called s3 is "happy" 288 return 0; 289 } s1 += s2 yields s1 = happy birthday s1 += " to you" yields Conversion constructor: to you Destructor: to you s1 = happy birthday to you Program Output

  39. Conversion constructor: happy birthday Copy constructor: happy birthday Destructor: happy birthday The substring of s1 starting at location 0 for 14 characters, s1(0, 14), is: happy birthday Destructor: happy birthday Conversion constructor: to you Copy constructor: to you Destructor: to you The substring of s1 starting at location 15, s1(15, 0), is: to you Destructor: to you Copy constructor: happy birthday to you *s4Ptr = happy birthday to you assigning *s4Ptr to *s4Ptr operator= called Attempted assignment of a String to itself *s4Ptr = happy birthday to you Destructor: happy birthday to you s1 after s1[0] = 'H' and s1[6] = 'B' is: Happy Birthday to you Attempt to assign 'd' to s1[30] yields: Assertion failed: subscript >= 0 && subscript < length, file string1.cpp, line 82 Abnormal program termination Program Output

  40. 8.11 Overloading ++ and -- • Pre/post incrementing/decrementing operators • Allowed to be overloaded • Distinguishing between pre and post operators • prefix versions are overloaded the same as other prefix unary operators d1.operator++(); // for ++d1 • convention adopted that when compiler sees postincrementing expression, it will generate the member-function call d1.operator++( 0 ); // for d1++ • 0 is a dummy value to make the argument list of operator++ distinguishable from the argument list for ++operator

  41. 8.12 Case Study: A Date Class • The following example creates a Date class with • An overloaded increment operator to change the day, month and year • An overloaded += operator • A function to test for leap years • A function to determine if a day is last day of a month

  42. 1 // Fig. 8.6: date1.h 2 // Definition of class Date 3 #ifndef DATE1_H 4 #define DATE1_H 5 #include <iostream> 6 7 using std::ostream; 8 9 class Date { 10 friend ostream &operator<<( ostream &, const Date & ); 11 12 public: 13 Date( int m = 1, int d = 1, int y = 1900 ); // constructor 14 void setDate( int, int, int ); // set the date 15 Date &operator++(); // preincrement operator 16 Date operator++( int ); // postincrement operator 17 const Date &operator+=( int ); // add days, modify object 18 bool leapYear( int ) const; // is this a leap year? 19 bool endOfMonth( int ) const; // is this end of month? 20 21 private: 22 int month; 23 int day; 24 int year; 25 26 static const int days[]; // array of days per month 27 void helpIncrement(); // utility function 28 }; 29 30 #endif 1. Class definition 1.1 Member functions 1.2 Member variables

  43. 31 // Fig. 8.6: date1.cpp 32 // Member function definitions for Date class 33 #include <iostream> 34 #include "date1.h" 35 36 // Initialize static member at file scope; 37 // one class-wide copy. 38 const int Date::days[] = { 0, 31, 28, 31, 30, 31, 30, 39 31, 31, 30, 31, 30, 31 }; 40 41 // Date constructor 42 Date::Date( int m, int d, int y ) { setDate( m, d, y ); } 43 44 // Set the date 45 void Date::setDate( int mm, int dd, int yy ) 46 { 47 month = ( mm >= 1 && mm <= 12 ) ? mm : 1; 48 year = ( yy >= 1900 && yy <= 2100 ) ? yy : 1900; 49 50 // test for a leap year 51 if ( month == 2 && leapYear( year ) ) 52 day = ( dd >= 1 && dd <= 29 ) ? dd : 1; 53 else 54 day = ( dd >= 1 && dd <= days[ month ] ) ? dd : 1; 55 } 56 57 // Preincrement operator overloaded as a member function. 58 Date &Date::operator++() 59 { 60 helpIncrement(); 61 return *this; // reference return to create an lvalue 62 } 63 1. Load header 1.1 Define days[] 1.2 Function definitions 1.3 Constructor 1.4 operator++ (preincrement)

  44. 64 // Postincrement operator overloaded as a member function. 65 // Note that the dummy integer parameter does not have a postincrement operator has a dummy int value. 66 // parameter name. 67 Date Date::operator++( int ) 68 { 69 Date temp = *this; 70 helpIncrement(); 71 72 // return non-incremented, saved, temporary object 73 return temp; // value return; not a reference return 74 } 75 76 // Add a specific number of days to a date 77 const Date &Date::operator+=( int additionalDays ) 78 { 79 for ( int i = 0; i < additionalDays; i++ ) 80 helpIncrement(); 81 82 return *this; // enables cascading 83 } 84 85 // If the year is a leap year, return true; 86 // otherwise, return false 87 bool Date::leapYear( int y ) const 88 { 89 if ( y % 400 == 0 || ( y % 100 != 0 && y % 4 == 0 ) ) 90 return true; // a leap year 91 else 92 return false; // not a leap year 93 } 94 95 // Determine if the day is the end of the month 96 bool Date::endOfMonth( int d ) const 97 { 1.5 operator++(int) (postincrement) 1.6 operator+= 1.7 leapYear 1.8 endOfMonth

  45. 98 if ( month == 2 && leapYear( year ) ) 99 return d == 29; // last day of Feb. in leap year 100 else 101 return d == days[ month ]; 102 } 103 104 // Function to help increment the date 105 void Date::helpIncrement() 106 { 107 if ( endOfMonth( day ) && month == 12 ) { // end year 108 day = 1; 109 month = 1; 110 ++year; 111 } 112 elseif ( endOfMonth( day ) ) { // end month 113 day = 1; 114 ++month; 115 } 116 else // not end of month or year; increment day 117 ++day; 118 } 119 120 // Overloaded output operator 121 ostream &operator<<( ostream &output, const Date &d ) 122 { 123 static char *monthName[ 13 ] = { "", "January", 124 "February", "March", "April", "May", "June", 125 "July", "August", "September", "October", 126 "November", "December" }; 127 128 output << monthName[ d.month ] << ' ' 129 << d.day << ", " << d.year; 130 131 return output; // enables cascading 132 } 1.9 helpIncrement 1.10 operator<< (output Date)

  46. 133 // Fig. 8.6: fig08_06.cpp 134 // Driver for class Date 135 #include <iostream> 136 137 using std::cout; 138 using std::endl; 139 140 #include "date1.h" 141 142 int main() 143 { 144 Date d1, d2( 12, 27, 1992 ), d3( 0, 99, 8045 ); 145 cout << "d1 is " << d1 146 << "\nd2 is " << d2 147 << "\nd3 is " << d3 << "\n\n"; 148 149 cout << "d2 += 7 is " << ( d2 += 7 ) << "\n\n"; 150 151 d3.setDate( 2, 28, 1992 ); 152 cout << " d3 is " << d3; 153 cout << "\n++d3 is " << ++d3 << "\n\n"; 154 155 Date d4( 3, 18, 1969 ); 156 157 cout << "Testing the preincrement operator:\n" 158 << " d4 is " << d4 << '\n'; 159 cout << "++d4 is " << ++d4 << '\n'; 160 cout << " d4 is " << d4 << "\n\n"; 161 162 cout << "Testing the postincrement operator:\n" 163 << " d4 is " << d4 << '\n'; 164 cout << "d4++ is " << d4++ << '\n'; 165 cout << " d4 is " << d4 << endl; 166 167 return 0; 168 } 1. Load header 1.1 Initialize objects 2. Function calls 3. Print results d1 is January 1, 1900 d2 is December 27, 1992 d3 is January 1, 1900 d2 += 7 is January 3, 1993 d3 is February 28, 1992 ++d3 is February 29, 1992 Testing the preincrement operator: d4 is March 18, 1969 ++d4 is March 19, 1969 d4 is March 19, 1969 Testing the preincrement operator: d4 is March 18, 1969 ++d4 is March 19, 1969 d4 is March 19, 1969

  47. d1 is January 1, 1900 d2 is December 27, 1992 d3 is January 1, 1900 d2 += 7 is January 3, 1993 d3 is February 28, 1992 ++d3 is February 29, 1992 Testing the preincrement operator: d4 is March 18, 1969 ++d4 is March 19, 1969 d4 is March 19, 1969 Testing the postincrement operator: d4 is March 19, 1969 d4++ is March 19, 1969 d4 is March 20, 1969 Program Output

More Related